Dr. Ji-Wei Ren | Organic Chemistry | Best Researcher Award

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Dr. Ji-Wei Ren | Organic Chemistry | Best Researcher Award

Dr. Ji-Wei Ren, Organic Chemistry, Taishan University , China 

Dr. Ji-Wei Ren is a Lecturer in the College of Chemistry and Chemical Engineering at Taishan University, China. He earned his Ph.D. in Chemical Engineering and Technology from Central South University, where he developed expertise in visible light catalysis, organo catalysis, and green synthesis. Dr. Ren has previously served as a Research Associate at Ningbo University’s Institute of Drug Discovery Technology, engaging in interdisciplinary research on biomimetic reducing agents and chiral resolution. With a strong foundation in heterocyclic construction and peptide synthesis, his work integrates sustainable and biomimetic chemistry with modern synthetic methodologies. Dr. Ren has published multiple high-impact research articles in leading journals such as Org. Lett., J. Org. Chem., and Org. Chem. Front.. His research is characterized by innovation, precision, and relevance to both pharmaceutical and materials chemistry. He actively contributes to academic platforms like ORCID and collaborates with renowned scientists across China.

Professional Profile :         

Orcid

Scopus 

Summary of Suitability for Award:

Dr. Ji-Wei Ren exemplifies the qualities of an outstanding researcher through his pioneering work in the field of organic synthesis, particularly in visible light catalysis, organocatalysis, and green chemistry. He has published over 11 peer-reviewed articles in top-tier journals such as Organic Chemistry Frontiers, Journal of Organic Chemistry, Organic Letters, and Chemistry – A European Journal. Several of his works have been highlighted by Synfacts, showcasing their novelty and scientific impact. His innovative contributions include the development of racemization-free synthesis protocols, the application of biomimetic reducing agents, and the design of sustainable methodologies for heterocycle and peptide construction. He brings a fresh perspective to traditional synthetic methods by incorporating visible light and bio-inspired techniques, addressing both the efficiency and environmental responsibility in chemical synthesis. Dr. Ji-Wei Ren is highly suitable for the “Best Researcher Award”. His significant scientific output, innovation in research, recognition by the international community, and dedication to sustainable chemistry clearly distinguish him as a leading researcher in his field. His commitment to impactful and environmentally conscious science makes him not only an excellent candidate but also a role model for emerging researchers. This award would be a deserving recognition of his ongoing contributions to the scientific world.

🎓Education:

Dr. Ji-Wei Ren completed both his undergraduate and doctoral studies at Central South University. He earned his Bachelor of Engineering in Pharmaceutical Engineering in June 2013, where he gained foundational knowledge in pharmaceutical chemistry, drug design, and synthesis. Subsequently, he pursued a Doctorate in Chemical Engineering and Technology (2013–2019) at the same university. His Ph.D. research focused on innovative synthetic strategies using organo catalysis and visible-light-driven methodologies for the construction of functional molecules, especially in the development of peptide and heterocyclic compounds. Under the mentorship of distinguished faculty, he honed his skills in reaction design, stereoselective synthesis, and catalysis. His academic training also included a deep understanding of biomimetic reactions, green synthesis, and photochemical transformations. This robust educational background laid the groundwork for his interdisciplinary research efforts, enabling him to contribute significantly to the fields of sustainable and asymmetric synthesis.

🏢Work Experience:

Dr. Ji-Wei Ren began his academic career as a Research Associate (2019–2022) at the Institute of Drug Discovery Technology, Ningbo University, where he focused on peptide synthesis and the development of bio-inspired reducing agents. His role involved collaborative projects in pharmaceutical chemistry and catalysis, contributing to the advancement of efficient and eco-friendly synthetic methods. In August 2022, he joined Taishan University as a Lecturer in the College of Chemistry and Chemical Engineering. At Taishan University, Dr. Ren continues his research in visible light catalysis and organocatalytic transformations, guiding students in advanced organic chemistry techniques and experimental methodologies. He has also contributed to curriculum development and interdisciplinary research programs. His teaching and research philosophy is rooted in innovation, sustainability, and student engagement. With over a decade of academic training and research, Dr. Ren combines a strong theoretical foundation with hands-on experience in both industrial and academic labs.

🏅Awards: 

Dr. Ji-Wei Ren has been consistently recognized for his impactful contributions to organic chemistry and green synthesis methodologies. His 2021 publication in Organic Letters was highlighted by Synfacts in 2022 for its innovative racemization-free synthesis approach, underlining the originality and practical importance of his work. Additionally, his earlier work in The Journal of Organic Chemistry (2017) was also spotlighted in Synfacts, reflecting his ongoing excellence in visible light-mediated and organocatalytic transformations. During his doctoral studies at Central South University, he was honored with multiple academic excellence awards for his outstanding research and scholarly dedication. His publications in top-tier journals like Organic Chemistry Frontiers, Organic & Biomolecular Chemistry, and Chemistry – A European Journal have further established him as a rising expert in his field. These recognitions underscore both the scientific value and the practical applicability of his research in modern organic synthesis.

🔬Research Focus:

Dr. Ji-Wei Ren’s research is centered on the development of innovative, environmentally friendly methodologies in organic synthesis. His primary interests lie in visible light catalysis, where he designs photochemical processes to enable mild and selective transformations. He is also deeply involved in chiral resolution and organocatalysis, with a particular emphasis on enantioselective reactions that are crucial for pharmaceutical synthesis. A significant part of his work involves constructing complex heterocyclic compounds, often using biomimetic and green synthesis strategies to reduce environmental impact. Dr. Ren has pioneered the use of L-amino acid esters as biomimetic reducing agents and introduced new deoxygenation and amidation protocols that avoid racemization—critical for peptide and amide bond formation. His interdisciplinary approach blends traditional organic chemistry with sustainability, aiming to create scalable, efficient, and selective processes suitable for industrial application. His contributions significantly enhance both academic understanding and practical implementation in organic synthesis.

Publication Top Notes:

“A visible light-mediated deoxygenation protocol for the synthesis of dipeptides, amides and esters without racemization”

“L-Amino acid ester as a biomimetic reducing agent for the reduction of unsaturated C=C bonds”

“Umpolung Strategy for the One-Pot Synthesis of Highly Steric Bispirooxindoles via the L-Amino Acid Ester-Promoted In Situ Reduction/Nucleophilic Addition/Cyclization Cascade Reaction”

“A visible light-induced deoxygenative amidation protocol for the synthesis of dipeptides and amides”

“An organocatalytic enantioselective ring-reorganization domino sequence of methyleneindolinones with 2-aminomalonates”

“Straightforward Synthesis of 3-Selenocyanato-Substituted Chromones through Electrophilic Selenocyanation of Enaminones under Grinding Conditions”

“Organocatalytic, Enantioselective, Polarity-Matched Ring-Reorganization Domino Sequence Based on the 3-Oxindole Scaffold”

“A One‐Pot Ring‐Opening/Ring‐Closure Sequence for the Synthesis of Polycyclic Spirooxindoles”

“L-Pyroglutamic Sulphonamide as Hydrogen-Bonding Organocatalyst: Enantioselective Diels–Alder Cyclization to Construct Carbazolespirooxindoles”

“Acid-Relayed Organocatalytic exo-Diels-Alder Cycloaddition of Cyclic Enones with 2-Vinyl-1H-indoles”

 

Dr. SHEKHAR RAPARTHI | Analytical Chemistry | Best Researcher Award

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Dr. SHEKHAR RAPARTHI | Analytical Chemistry | Best Researcher Award

Dr. SHEKHAR RAPARTHI | Analytical Chemistry | SCIENTIFIC OFFICER/H at NATIONAL CENTER FOR COMPOSITIONAL CHARACTERISATION OF MATERIALS,  India

Shekhar Raparthi is a Scientific Officer / H at the National Centre for Compositional Characterisation of Materials (NCCCM), BARC, Hyderabad. With over three decades of expertise in analytical chemistry, he specializes in trace and ultra-trace characterization of metals, alloys, and high-purity materials. His pioneering work in glow discharge quadrupole mass spectrometry and electrolyte cathode discharge atomic emission spectrometry has significantly advanced compositional analysis. Holding a Ph.D. in Chemistry from JNTU, Hyderabad (2008), he has published extensively in reputed international journals and served as a peer reviewer. Currently leading the ultra-trace analysis section at NCCCM since 2023, he is an esteemed member of India Society for Mass Spectrometry (ISMAS) and Indian Society of Analytical Science (ISAS). His contributions to spectrometric techniques have practical applications in industrial and nuclear material characterization, making him a respected figure in analytical and green chemistry research.

Professional Profile :         

Scopus  

Summary of Suitability for Award:

Dr. Shekhar Raparthi is a highly accomplished researcher specializing in trace and ultra-trace characterization of materials using mass and spectrometric techniques. With over 32 publications in high-impact journals, an h-index of 14, and 631 citations, he has made significant contributions to analytical chemistry. His pioneering research includes the development of infrared spectroscopic methods, glow discharge quadrupole mass spectrometry (GD-QMS), and novel electrolyte cathode discharge atomic emission spectrometric sources. These innovations have advanced material characterization techniques, benefiting the scientific community and industries dealing with high-purity materials, metals, and alloys. Dr. Raparthi’s extensive research contributions, innovative methodologies, and commitment to advancing analytical chemistry make him an ideal candidate for the “Best Researcher Award.” His work has been recognized through numerous international publications, and his role as the head of the ultra-trace analysis section at NCCCM, BARC, further solidifies his impact in the field.

🎓Education:

Shekhar Raparthi pursued his M.Sc. in Chemistry from the University of Hyderabad in 1993, where he developed a strong foundation in analytical chemistry. Following this, he underwent a one-year orientation program at BARC in 1994, gaining specialized training in advanced compositional characterization techniques. His academic journey culminated in a Ph.D. in Chemistry from Jawaharlal Nehru Technological University (JNTU), Hyderabad, in 2008. His doctoral research focused on the development of advanced mass spectrometric methodologies for the ultra-trace analysis of metals and high-purity materials. Over the years, he has continuously expanded his expertise through research, peer-reviewed publications, and participation in international analytical chemistry conferences. His educational background has been instrumental in his ability to innovate in trace and ultra-trace analysis techniques, making significant contributions to the field of analytical chemistry.

🏢Work Experience:

Shekhar Raparthi began his professional career in 1994 as a Scientific Officer/C at NCCCM, BARC, Hyderabad, specializing in the compositional characterization of various materials. Over the past 30 years, he has developed novel analytical methodologies for metals, alloys, and high-purity materials using mass spectrometric and spectroscopic techniques. His expertise includes glow discharge quadrupole mass spectrometry and electrolyte cathode discharge atomic emission spectrometry, contributing to advancements in trace and ultra-trace analysis. His work has been widely recognized, leading to 32 publications in reputed international journals. Since 2023, he has been heading the ultra-trace analysis section at NCCCM, overseeing critical research in compositional characterization. He is also an active peer reviewer for international journals. With extensive experience in spectrometric techniques, Shekhar Raparthi plays a key role in material characterization for nuclear, industrial, and high-tech applications.

🏅Awards: 

Shekhar Raparthi has received several accolades for his significant contributions to analytical chemistry and mass spectrometry. His infrared spectroscopic method for oxygen quantification in TiCl₄ was widely appreciated in the titanium industry, earning him recognition in the field. His research on glow discharge quadrupole mass spectrometry and matrix volatilization methodologies for ultra-trace characterization of high-purity germanium has been published in top international journals, including Analytical Chemistry. His expertise in trace element analysis has made him a valuable asset to BARC and the Indian scientific community. As a distinguished member of ISMAS and ISAS, he actively contributes to the advancement of analytical sciences in India. While he has not listed specific awards, his impactful research, numerous peer-reviewed publications, and leadership in ultra-trace analysis solidify his reputation as a leading scientist in compositional characterization.

🔬Research Focus:

Shekhar Raparthi’s research revolves around trace and ultra-trace characterization of materials using advanced mass spectrometric and spectroscopic techniques. His work plays a crucial role in ensuring the purity and compositional accuracy of metals, alloys, and high-purity materials. He has pioneered glow discharge quadrupole mass spectrometry (GD-QMS) for detecting impurities at ultra-trace levels. Additionally, his development of matrix volatilization methodologies has enhanced the characterization of high-purity germanium, a material critical in semiconductor and radiation detection applications. His innovations in electrolyte cathode discharge atomic emission spectrometry (ECD-AES) have improved the sensitivity and precision of trace element analysis. His research significantly contributes to nuclear, industrial, and advanced material applications, ensuring high accuracy in material compositional studies. As the head of the ultra-trace analysis section at NCCCM, his expertise in **

Publication Top Notes:

In-situ Ti–Ir and ammonium thiocyanate modifiers for improvement of sensitivity of Sc to sub parts per billion levels and its accurate quantification in coal fly ash and red mud by GFAAS

Hydrophobicity induced graphene oxide based dispersive micro solid phase extraction of strontium from seawater and groundwater prior to GFAAS determination

Direct determination of ultra-trace sodium in reactor secondary coolant waters and other waters by electrolyte cathode discharge atomic emission spectrometry

Citation Count: 1